Materials for Energy Storage

High capacity Li4Ti5O12 anode for Li-ion battery applications Subcategory (under Clean Energy): Storage Technology Readiness Level (TRL): TRL 4 – Early prototype Technology Outline (Process Description) Sol-gel synthesis has been established for scaled-up synthesis of cathode material. Sol-gel synthesis in brief: LiMn2O4 will be synthesized using lithium acetate and manganese (II) acetate tetrahydrate dissolved in […]

System and Method for Monitoring Battery Health using Image Analysis through Deep-learning Subcategory (under Clean Energy): Storage Technology Readiness Level (TRL): TRL 4 – Early prototype Technology Outline (Process Description) The battery health monitoring system consists of an image capturing unit, algorithms for system regulation, and a data-driven model for fast predicting the State of

MXene Using Eco-Friendly Electrolyte Subcategory (under Clean Energy): Cross Cutting Technology Readiness Level (TRL): TRL 4 – Early prototype Technology Outline (Process Description) A new family of atomically thin and two-dimensional (2D) layered materials is emerging as a result of the successful discovery of graphene. Transition metal carbides and nitrides known as MXene, a fascinating

Si Anode development for very high- capacity Li-ion battery Subcategory (under Clean Energy): Storage Technology Readiness Level (TRL): TRL 5 – Large prototype Technology Outline (Process Description) Li-ion batteries are the most powerful energy storage technologies having high energy density and long cycle life. Replacing the present commercial anode material, i.e., graphite with Si (properly

Different Energy Vector Integration for Storage of Energy (DEVISE) Subcategory (under Clean Energy): Cross Cutting Technology Readiness Level (TRL): TRL 4 – Early prototype Technology Outline (Process Description) DEVISE aims to create a comprehensive storage system that can efficiently and rationally utilize all forms of energy. This will be achieved by creating a heterogeneous storage

Cascaded Latent Heat Storage (CLHS) for hightemperature CSP applications material development and characterization to lab-scale setup Subcategory (under Clean Energy): Cross Cutting Technology Readiness Level (TRL): TRL 4 – Early prototype Technology Outline (Process Description) The present research is attributed to the cascaded latent heat storage (CLHS) concept to ensure the maximization of thermal energy

Electrospun Nanofibers as Effective Polysulfide Trap for Advanced Lithium-Sulfur Batteries Subcategory (under Clean Energy): Cross Cutting Technology Readiness Level (TRL): TRL 4 – Early prototype Technology Outline (Process Description) In this project, fibrous cathode materials and solid-state electrolytes were developed with the use of low-cost processing techniques to overcome the persistent problem of Lithium Sulfur

Development of Hybrid 3D Architecture Electrodes for High Energy Density Supercapattery Subcategory (under Clean Energy): Storage Technology Readiness Level (TRL): TRL 4 – Early prototype Technology Outline (Process Description) Predominantly supercapacitors (SC) are beneficial energy storage devices because of their exceedingly competent charge storage capability, cyclic stability, power density, and rate capability. But the commercialization

High voltage carbon encapsulated-graded LiMn2O4:LiNi1-x-yCoxAlyO2 cathodes for rechargeable Li-ion pouch cells Subcategory (under Clean Energy): Cross Cutting Technology Readiness Level (TRL): TRL 4 – Early prototype Technology Outline (Process Description) The mileage per charge of an electric vehicle depends on the practical energy density of its lithium-ion battery’s cathode materials. The energy density relies on

Ion-exchange membranes Subcategory (under Clean Energy): Cross Cutting Technology Readiness Level (TRL): TRL 4 – Early prototype Technology Outline (Process Description) Ion exchange membranes are unique to many advanced energy devices. Their uniqueness comes from selectivity, permeability and ionic transport at elevated temperature and extremely oxidative environment. Their chemical and dimensional stability decides the specific